Water waves produced by a motor boat sailing in water are
A. Neither longitudinal nor transverse.
B. Both longitudinal and transverse.
C. Only longitudinal.
D. Only transverse.
On the surface water transverse waves are produced due to the production of longitudinal waves produced by the rudder inside the water. So, both transverse and longitudinal waves are produced.
Sound waves of wavelength λ travelling in a medium with a speed of v m/s enter into another medium where its speed is 2v m/s. Wavelength of sound waves in the second medium is
A. λ
B.
C. 2λ
D. 4λ
Wavelength in 1st medium = --------------------- (i)
Wavelength in 2nd medium= ------------------------------ (ii)
(ii)÷ (i), we get;
Or
Speed of sound wave in air
A. is independent of temperature.
B. Increases with pressure.
C. Increases with increase in humidity.
D. Decreases with increase in humidity
If the humidity increases, then the density of air decreases and thus, speed of sound increases with increase in humidity.
Change in temperature of the medium changes
A. Frequency of sound waves
B. Amplitude of sound waves
C. Wavelength of sound waves.
D. Loudness of sound waves
Speed of sound is directly proportional to the square root of temperature.
If temperature changes, the speed also changes and thus wavelength changes.
(Here, frequency n is constant)
With propagation of longitudinal waves through a medium, the quantity transmitted is
A. Matter.
B. Energy.
C. Energy and matter.
D. Energy, matter and momentum.
A wave (sound wave, light wave, radio wave) is a disturbance and it only transmits the energy from one place to another, without making any change in matter and momentum.
Which of the following statements are true for wave motion?
A. Mechanical transverse waves can propagate through all mediums.
B. Longitudinal waves can propagate through solids only
C. Mechanical transverse waves can propagate through solids only.
D. Longitudinal waves can propagate through vacuum.
Solids and strings possess shear module. When mechanical waves propagate through solids is subjected to shearing stress. This is the reason the sustain shearing stress.
A sound wave is passing through air column in the form of compression and rarefaction. In consecutive compressions and rarefactions,
A. Density remains constant.
B. Boyle’s law is obeyed.
C. Bulk modulus of air oscillates.
D. There is no transfer of heat.
A sound wave always propagates in column by compression and rarefaction. The time taken in compression and rarefaction is very small and we can assume it as adiabatic process, hence no transfer of heat occurs.
Equation of a plane progressive wave is given by . On reflection from a denser medium its amplitude becomes 2/3 of the amplitude of the incident wave. The equation of the reflected wave is
A. 0.6sin2 π
B. Y = -0.4 sin 2π
C. Y = 0.4 sin 2 π
D. Y = -0.4 sin 2π
A plane progressive wave is reflected from denser medium to rarer medium.
Amplitude of reflected wave = × 0.6 = 0.4
Since, wave is reflected from denser to rarer medium, there is a phase change in π
= 0.4 sin 2 π
0.4 sin 2 π
A string of mass 2.5 kg is under a tension of 200 N. The length of the stretched string is 20.0 m. If the transverse jerk is struck at one end of the string, the disturbance will reach the other end in
A. one second
B. 0.5 second
C. 2 seconds
D. data given is insufficient.
Given,
The tension in the string (T) is 200 N
Mass of the string = L = 2.5 kg
The length of the stretched string = 20.0 m
Now the mass per unit length of the string is given by μ,
The velocity (v) of transverse wave of the string is given by the relation;
So, the time taken by the disturbance to reach the end of the string,
Hence option B is the correct answer.
A train whistling at constant frequency is moving towards a station at a constant speed V. The train goes past a stationary observer on the station. The frequency n′ of the sound as heard by the observer is plotted as a function of time t (Fig 15.1). Identify the expected curve.
A.
B.
C.
D.
When the train is coming towards the observer
Apparent frequency
Now;
The train is going away from the observer
Apparent frequency
So,
The curve formed is C.
A transverse harmonic wave on a string is described by Where x and y are in cm and t is in s. The positive direction of x is from left to right.
A. The wave is travelling from right to left.
B. The speed of the wave is 20m/s.
C. Frequency of the wave is 5.7 Hz.
D. The least distance between two successive crests in the wave is 2.5 cm.
D. The least distance between two successive crests in the wave is 2.5 cm. This statement is incorrect
Explanation: The least distance between two successive crests in wavelength
The displacement of a string is given by Where and are in m and t in s. The length of the string is 1.5m and its mass is.
A. It represents a progressive wave of frequency 60Hz.
B. It represents a stationary wave of frequency 60Hz.
C. It is the result of superposition of two waves of wavelength 3 m, frequency 60Hz each travelling with a speed of 180 m/s in opposite direction.
D. Amplitude of this wave is constant.
C. It is the result of superposition of two waves of wavelength 3 m, frequency 60Hz each travelling with a
Speed of 180 m/s in opposite direction.
Explanation: As the equation involves harmonic functions and separately, it represents a stationary wave.
The given equation is: ------------------- (i)
Which is travelling along positive x-axis and is superimposed by the reflected wave
Also, is a stationary wave travelling in opposite direction
------------------------ (ii)
By comparing equations (i) and (ii),
Also,
Or,
Frequency
Speed of sound waves in a fluid depends upon
A. Directly on density of the medium.
B. Square of Bulk modulus of the medium.
C. Inversely on the square root of density.
D. Directly on the square root of bulk modulus of the medium.
D. Directly on the square root of bulk modulus of the medium.
Explanation: speed of sound wave in fluid becomes
------------------ (i)
After separating the equation (i), we get;
And
During propagation of a plane progressive mechanical wave
A. All the particles are vibrating in the same phase.
B. Amplitude of all the particles is equal.
C. Particles of the medium executes S.H.M.
D. Wave velocity depends upon the nature of the medium.
C. Particles of the medium executes S.H.M.
D. Wave velocity depends upon the nature of the medium.
Explanation: When a move motion passes through any medium, particles of that medium vibrates harmonically at their position. The particles of medium oscillate with same frequency and the amplitude of the medium particles is also same. Velocity of a wave motion of a particular medium is constant and they only depend on the nature of the medium not on the frequency, wavelength or intensity of the wave.
The transverse displacement of a string (clamped at its both ends) is given by:
All the points on the string between two consecutive nodes vibrate with
A. Same frequency
B. Same phase
C. Same energy
D. Different amplitude.
Given that;
It represents the equation of a stationary wave. All the points on the string vibrate with same frequency between two nodes. But, they have different amplitudes. And due to different amplitudes they have different energies.
A train, standing in a station yard, blows a whistle of frequency 400 Hz in still air. The wind starts blowing in the direction from the yard to the station with a speed of 10m/s. Given that the speed of sound in still air is 340m/s,
A. The frequency of sound as heard by an observer standing on the platform is 400Hz.
B. The speed of sound for the observer standing on the platform is 350m/s.
C. The frequency of sound as heard by the observer standing on the platform will increase.
D. The frequency of sound as heard by the observer standing on the platform will decrease.
There no relative motion between the train and the observer, so the frequency heard by the observer is same as the frequency produced by the train.
The wind is blowing at a speed of 10m\sec in the direction in which sound wave is travelling. So, net speed of sound wave is = (350+10) m\sec = 350 m\sec.
Which of the following statements are true for a stationary wave?
A. Every particle has fixed amplitude which is different from the amplitude of its nearest particle.
B. All the particles cross their mean position at the same time.
C. All the particles are oscillating with same amplitude.
D. There is no net transfer of energy across any plane.
E. There are some particles which are always at rest.
âIn a stationary wave any particle at its given position has fixed amplitude of.
âThe oscillations time period of all the particles are same. So, they all cross their mean position at the same time.
âThere no transfer of heat between nodes because nodes are the points which are always at rest position.
A Sonometer wire is vibrating in resonance with a tuning fork. Keeping the tension applied same; the length of the wire is doubled. Under what conditions would the tuning fork still be in resonance with the wire?
When wire of length L is made to vibrate, its resonance frequency in nth mode after stretching it by tension T, then Frequency
[Here, m= mass per unit length of stretched wire]
The two given cases are:
---------------------- (i)
---------------------- (ii)
According to question;
(Mass of wire m is same in both cases)
Equation (i) divided by Equation (ii);
Since, the turning forks in the both cases are also same.
.
.
Hence, when the length of wire is doubled, the number of harmonic wave also doubles for same resonant frequency.
An organ pipe of length L open at both ends is found to vibrate in its first harmonic when sounded with a tuning fork of 480 Hz. What should be the length of a pipe closed at one end, so that it also vibrates in its first harmonic with the same tuning fork?
For first harmonic, the reference diagram is:
The pipe is open with both ends.
Or
Or,
Now, the pipe is closed with one end:
[The speed is constant]
Or
A tuning fork A, marked 512 Hz, produces 5 beats per second, where sounded with another unmarked tuning fork B. If B is loaded with wax the number of beats is again 5 per second. What is the frequency of the tuning fork B when not loaded?
Frequency of tuning fork A:
Tuning fork, A produces 5 beats per second.
When tuning fork B is loaded with wax, then also it produces 5 beats\second.
Now, the frequency of tuning fork B may be:
= 512 5
= 517 Hz or 507 Hz
If the frequency of tuning fork B is 517 Hz, it will reduce to 507 Hz making 5 beats\second and if the frequency of tuning fork B is 507 Hz, it will increase to 517 Hz again making 5 beats\second.
The displacement of an elastic wave is given by the function y = 3 sin ωt + 4 cos ωt. where y is in cm and t is in second. Calculate the resultant amplitude.
Given:
Displacement equation of an elastic wave y = 3sinωt + 4cosωt
Let 3 = Acosθ and 4 = Asinθ, then the equation for displacement becomes:
by using the property
we have ,
Which is the equation for a simple harmonic wave with amplitude A and phase difference θ. For θ we have
For amplitude A, squaring and adding 3 = Acosθ and 4 = Asinθ, we have
And
Therefore, the equation for the wave becomes
with its amplitude being 5 m.
A sitar wire is replaced by another wire of same length and material but of three times the earlier radius. If the tension in the wire remains the same, by what factor will the frequency change?
We know that the frequency if wire in tension is given by the equation
where n is the number of node, l is the length of the wire, T is the tension of the wire and μ is the mass per unit length of the wire. Let r be the radius of the wire and ρ be its density, then mass per unit length is given by,
then the frequency becomes
when r = 3r,
Therefore, when the radius is tripled the frequency is reduced by a factor of .
At what temperatures (in ° C) will the speed of sound in air be 3 times its value at 0°C?
Given:
Initial temperature of air = 0° C = 273.15 K
We know that the speed of sound in air is given by the equation,
where γ is the ratio of specific heat at constant pressure to specific heat at constant volume for air, R is the universal gas constant, T is temperature and M is the mass of the gas. Keeping everything constant except temperature,
Let the velocity of sound in air at 0° C be v0 and the velocity at temperature T be vt, then
When vt=3v0
When two waves of almost equal frequencies n 1 and n 2 reach at a point simultaneously, what is the time interval between successive maxima?
Given:
Frequency of first wave = n1
Frequency of second wave = n2
Let n1>n2. When these two waves interfere having slightly different frequencies they will produce beats. The beat frequency would be
The time period of the beat is equal to the time interval between successive maxima therefore,
A steel wire has a length of 12 m and a mass of 2.10 kg. What will be the speed of a transverse wave on this wire when a tension of 2.06 × 104 N is applied?
Given:
Length of wire = 12 m
Mass of wire = 2.1 kg
Tension applied = 2.06 x 104 N
We know that the speed of a transverse wave on a wire is given by,
where T is the tension in the wire and μ is the mass per unit length. Now
and
Then speed,
A pipe 20 cm long is closed at one end. Which harmonic mode of the pipe is resonantly excited by a source of 1237.5 Hz? (sound velocity in air = 330 m s-1)
Given:
Length of pipe l = 20 cm
Frequency of wave = 1237.5 Hz
We know that the for a pipe closed at one end the resonant frequency of the pipe is given by
where n is the harmonic, v is the speed of the wave and l is the length of the pipe. For first harmonic or fundamental frequency we have n = 1, then
for a frequency of 1237.5 Hz,
Therefore, the given frequency corresponds to the third harmonic.
A train standing at the outer signal of a railway station blows a whistle of frequency 400 Hz still air. The train begins to move with a speed of 10 m s-1 towards the platform. What is the frequency of the sound for an observer standing on the platform? (sound velocity in air = 330 m s-1)
Given:
Frequency of whistle = 400 Hz
Speed of train = 10 ms-1
When the train starts moving the source of the sound is also moving from the observer, thus the waves emitted by the source starts shifting as the train moves which creates a change in frequency of the sound reaching the observer. This effect is called Doppler effect. The apparent frequency of the sound for the observer is given by the relation,
Where v is the speed of sound in air, vt is the speed of the train and f is the original frequency.
Therefore the sound reaching the observer will have a frequency of 412.5 Hz.
The wave pattern on a stretched string is shown in Fig. 15.2. Interpret what kind of wave this is and find its wavelength.
The given wave is a standing wave. From the given figure we can see that it is transverse wave as it vibrates at right angle to its direction of propagation. Also from the graph the equation of the wave can be determined as
and
where ω is the angular frequency and T is the time period. The given wave has nodes at displacements of 10, 20, 30, 50 units of displacement. The distance between two successive nodes is equal to half the wavelength, therefore
The pattern of standing waves formed on a stretched string at two instants of time are shown in Fig. 15.3. The velocity of two waves superimposing to form stationary waves is 360 ms-1 and their frequencies are 256 Hz.
(a) Calculate the time at which the second curve is plotted.
(b) Mark nodes and antinodes on the curve.
(c) Calculate the distance between A′ and C′.
Given:
Frequency of the wave = 256 Hz
Velocity of the wave = 360ms-1
(a) In the second instant, all the points of the wave are at the mean position. The time taken to reach the mean position from the amplitude is therefore the time at which the second curve is plotted. The distance to reach the mean position from the amplitude is distance between a node and an antinode that equals one-fourth the wavelength. The wavelength therefore is given by,
where v is the velocity and f is the frequency of the wave.
And
Therefore time taken to reach mean position,
Therefore, the second curve was plotted at time of t = 9.72 x 10-4 s.
(b) Nodes are points that undergo the minimum displacement and antinodes are points that undergo the maximum displacement. Thus, the points A, B, C, D, E, are the node and the points A’ and C’ are the antinodes.
(c) A’ and C’ are successive antinodes, and the distance between two successive antinodes is the wavelength of the wave, therefore
A tuning fork vibrating with a frequency of 512Hz is kept close to the open end of a tube filled with water (Fig. 15.4). The water level in the tube is gradually lowered. When the water level is 17cm below the open end, maximum intensity of sound is heard. If the room temperature is 20° C, calculate
(a) speed of sound in air at room temperature
(b) speed of sound in air at 0° C
(c) if the water in the tube is replaced with mercury, will there be any difference in your observations?
Given:
Frequency of tuning fork = 512 Hz
Water level below open end = 17 cm
The water acts as a reflective surface for the wave, therefore the tube behaves like an organ pipe. When the water level is such that the frequency of the wave matches the resonant frequency of the organ pipe the maximum sound is heard.
(a) Since at 17 cm maximum intensity of sound is heard, it corresponds to amplitude of the wave. For the first harmonic the length of the organ pipe equals one-fourth the wavelength of the wave. Hence,
Where, l is the length of the pipe and λ is the wavelength
Now velocity of wave
where f is the frequency of the wave.
(b) We know that velocity of air is given by
where γ is the ratio of specific heat at constant pressure to specific heat at constant volume for air, R is the universal gas constant, T is temperature and M is the mass of the gas. Keeping everything constant except temperature,
Let the velocity of sound in air at 0° C be v0 and the velocity at temperature 20° be v20, then
(c) When water is replaced with mercury all the observations will remain same, however mercury is more reflective than water and therefore the intensity of the sound heard will be increased.
Show that when a string fixed at its two ends vibrates in 1 loop, 2 loops, 3 loops and 4 loops, the frequencies are in the ratio 1:2:3:4.
When a string is fixed at two ends then the equation for a wave on the sting is given by,
for a node y = 0, for which
For the string of length l, let one the position of one end be x = 0, then the position of other end will be x = L, therefore,
and the frequency
The frequencies for different values of n are called harmonics, for e.g. n =1 is called the first harmonic, n = 2 is the second harmonic and so on. Theses harmonics correspond to the number of loops for the vibrations. Thus the frequencies corresponding 1 loop, 2 loops, 3 loops and 4 loops are
respectively.
Hence these frequencies are in the ratio 1:2:3:4.
The earth has a radius of 6400 km. The inner core of 1000 km radius is solid. Outside it, there is a region from 1000 km to a radius of 3500 km which is in molten state. Then again from 3500 km to 6400 km the earth is solid. Only longitudinal (P) waves can travel inside a liquid. Assume that the P wave has a speed of 8 km s-1 in solid parts and of 5 km s-1 in liquid parts of the earth. An earthquake occurs at some place close to the surface of the earth. Calculate the time after which it will be recorded in a seismometer at a diametrically opposite point on the earth if wave travels along diameter?
Given:
Speed of longitudinal wave in solid = 8 kms-1
Speed of longitudinal wave in liquid = 5 kms-1
When the wave travels across the earth towards the core, it will pass the liquid region and the two solid regions. The first solid region starting from the crust has a radial distance of
For the molten region the radial distance is
And for the solid region of the core the distance is
The time taken to travel to the centre of earth from the crust is therefore,
where vs and vl are the velocities of the longitudinal wave in solid and liquid respectively.
To travel to a diametrical opposite point the time will be equal to 2t = 1975 s. Therefore, the seismometer will record the earthquake after 1975 seconds after the earthquake initiates.
If c is r.m.s. speed of molecules in a gas and v is the speed of sound waves in the gas, show that c/v is constant and independent of temperature for all diatomic gases.
From kinetic theory of gases, the rms speed of molecules of a gas is given by,
where P is the pressure of the gas and ρ is the density. From ideal gas law
Where R is the universal gas constant, T is temperature and M is the molecular mass of the gas.
The speed of sound on the other hand is given by
where γ is the ratio of specific heat at constant pressure to specific heat at constant volume for air, R is the universal gas constant, T is temperature and M is the molecular mass of the gas.
Therefore
For a diatomic gas γ = 1.4, and hence
And is independent of temperature.
Given below are some functions of x and t to represent the displacement of an elastic wave.
(a) y = 5 cos (4x) sin (20t)
(b) y = 4 sin (5x – t/2) + 3 cos (5x – t/2)
(c) y = 10 cos [(252 – 250) πt ] cos [(252+250)πt ]
(d) y = 100 cos (100πt + 0.5x)
State which of these represent
(a) a travelling wave along –x direction
(b) a stationary wave
(c) beats
(d) a travelling wave along +x direction.
Given reasons for your answers.
(a) The given equation is
by using the property
The given equation can be represented as,
which is the superposition of the same progressive wave in the opposite direction and therefore is the equation of a stationery wave.
(b) The given equation represents a travelling wave along the +x direction as the equation has terms of (ωt - kx) which cannot be separated.
(c) the given equation is
using the property
The given equation can be represented as,
which is the superposition of two wave having very similar frequencies of 504 Hz and 500 Hz which constitute beats.
(d) The given equation represents a travelling wave along the -x direction as the equation has terms of (ωt + kx) which cannot be separated.
In the given progressive wave y = 5 sin (100πt – 0.4πx) where y and x are in m, t is in s. What is the
(a) amplitude
(b) wave length
(c) frequency
(d) wave velocity
(e) particle velocity amplitude.
Equation for a progressive wave y = 5sin(100πt-0.4πx)
Comparing the equation with the general displacement equation for a progressive wave,
we have
(a) Amplitude A = 5 m
(b) k = 0.4π. k is given by the relation
where λ is the wavelength. Therefore for k = 0.4π we have
(c) The angular frequency ω = 100π. The angular frequency is given by,
where f is the frequency of the wave.
(d) The wave velocity is given by the relation,
(e) Differentiating the given equation with respect to t we get the equation for particle velocity, i.e.
Therefore, the amplitude particle velocity is given by
For the harmonic travelling wave y = 2 cos 2π (10t–0.0080x + 3.5) where x and y are in cm and t is second. What is the phase difference between the oscillatory motion at two points separated by a distance of,
(a) 4 m
(b) 0.5 m
(c)
(d) (at a given instant of time)
(e) What is the phase difference between the oscillation of a particle located at x = 100cm, at t = T s and t = 5 s?
Given:
The equation of the wave y = 2cos[2π(10t-0.0080x+3.5)]
(a) For the wave separated by a distance of 4 m the equation of vibration will be,
or
and the phase
Comparing this equation to the original equation
and the phase
the phase difference therefore
(b) For a separation of 0.5 m, proceeding as above,
and the phase
Comparing this equation to the original equation its phase
the phase difference therefore
(c) The wavelength of the equation can be found by comparing the equation to the general equation for the wave,
we have, k = 0.016π and ω =20π. We know that k is related to the wavelength as
where λ is the wavelength. Therefore for k = 0.016π we have
For a separation of or 0.625 m,
and the phase
Comparing this equation to the original equation its phase
the phase difference therefore
(d) For a separation of or 0.938 m, proceeding as above
and the phase
Comparing this equation to the original equation its phase
the phase difference therefore
(e) At x = 100 cm the equation of the wave becomes,
We know that ω is and time period T are related as
but ω = 20π,
At t = T= 0.1 s the equation of the wave is given by,
and the phase
At t = 5 s the equation of the wave is given by,
and the phase
the phase difference therefore